CN113000118A - Organic starch production and processing system - Google Patents

Abstract

The invention relates to the technical field of starch processing, in particular to an organic starch production and processing system which comprises a workbench, a primary grinding mechanism, a secondary grinding mechanism and a conveying mechanism.

Description

Organic starch production and processing system

Technical Field

The invention relates to the technical field of starch processing, in particular to an organic starch production and processing system.

Background

Starch is polymerized from glucose molecules, which is the most common storage form of carbohydrate in cells, and is also called starch in catering industry, the general formula is (CHO) n, the hydrolysis stage to disaccharide is maltose, the chemical formula is CHO, monosaccharide (glucose) is obtained after complete hydrolysis, the chemical formula is CHO, starch has two types of amylose and amylopectin, starch is the nutrient stored in plant bodies and is stored in seeds and tubers, the starch content in various plants is high, the starch can be regarded as a high polymer of glucose, the starch is not only edible, but also used for preparing dextrin, maltose, glucose, alcohol and the like in industry, preparing printing paste, sizing textile, sizing paper, pressing drug tablets and the like, can be extracted from starch-containing substances such as corn, sweet potato, wild acorn, kudzu root and the like, but the following problems can occur in the starch extraction and grinding process:

1. in the traditional starch grinding process, the starch is ground manually, the grinding force is not enough due to misoperation when the starch is ground manually, and the working requirement cannot be met when a large amount of starch needs to be ground, so that the working efficiency is reduced;

2. when the starch needing to be ground is conveyed, a conveyor belt is generally adopted to directly convey the starch, so that the starch and impurities in the starch are mixed together and cannot be separated, and the working quality is reduced.

Disclosure of Invention

Technical scheme (I)

In order to achieve the purpose, the invention adopts the following technical scheme that the organic starch production and processing system comprises a workbench, a primary grinding mechanism, a secondary grinding mechanism and a conveying mechanism, wherein the primary grinding mechanism is arranged above the workbench, the secondary grinding mechanism is arranged below the primary grinding mechanism, and the conveying mechanism is arranged below the secondary grinding mechanism.

The first-stage grinding mechanism comprises a vertical plate, a connecting rod, a grinding box, a feeding hole, a feeding plate, a discharging hole, a discharging plate, a rotating shaft, a grinding roller, a gear, a machine base and a motor, wherein the vertical plate is symmetrically arranged in front of and behind the upper end surface of the workbench, the connecting rod is arranged on the opposite surfaces of the two vertical plates, the grinding box is jointly arranged on the opposite surfaces of the two connecting rods, the left end and the right end of the grinding box are in an arc shape, the left end and the right end of the grinding box are in an arc-shaped cavity structure, the feeding hole is arranged on the upper end surface of the grinding box, the feeding plate with an outward opening is arranged on the feeding hole, the feeding plate is in a rectangular shape, the discharging hole is arranged on the lower end surface of the grinding box, the discharging plate with an inward opening is arranged on the discharging hole, the discharging plate is in a rectangular shape, the first rotating shaft is symmetrically arranged between the two vertical plates through a, two first rotating shafts penetrate through the first grinding box, a first grinding roller is fixedly sleeved on each first rotating shaft, the two first grinding rollers are arranged in the first grinding box, conical protruding entities are uniformly distributed on each first grinding roller along the circumferential direction at equal intervals, a first gear is arranged on each first rotating shaft, the two first gears are in meshing transmission, a motor is arranged on one vertical plate through a base, an output shaft of the motor penetrates through the vertical plate to be connected with one first rotating shaft, starch blocks are placed in the feeding plate to fall onto the first grinding roller through a first feeding hole, the first rotating shaft is driven to rotate by the motor, the first gear is synchronously driven to rotate while the first rotating shaft is driven to rotate, the first gear is meshed with the other first gear for inward transmission when the first gear is meshed with the first gear for inward transmission, the first grinding roller is synchronously driven to rotate, make grinding roller carry out extrusion grinding to the starch piece No. one to the starch piece is broken, and the starch piece that has been ground by grinding roller extrusion grinding drops through ejection of compact board owing to the weight of self and a discharge gate and falls.

The second-stage grinding mechanism comprises a second connecting rod, a second grinding box, a second feeding hole, a second discharging hole, a second rotating shaft, a second grinding roller, a first belt and a second gear, wherein the second connecting rod is arranged on the opposite surfaces of the two vertical plates, the second grinding box is jointly arranged on the opposite surfaces of the two second connecting rods, the left and right ends of the second grinding box are arc-shaped cavity structures, the upper end surface of the second grinding box is provided with the second feeding hole, the lower end surface of the second grinding box is provided with the second discharging hole, the second rotating shaft is symmetrically arranged between the two vertical plates through a bearing, the two second rotating shafts penetrate through the second grinding box, the second grinding roller is fixedly sleeved on the two second rotating shafts, the two second grinding rollers are arranged in the second grinding box, one of the first rotating shafts is in transmission connection with one of the second rotating shafts corresponding to each other of the first rotating shafts up and down through the first belt, all fixed cover is equipped with No. two gears in No. two axis of rotation, two No. two gears are the meshing transmission, when the motor drives an axis of rotation and rotates, one of them axis of rotation drives one of them No. two axis of rotation and one of them No. two gears rotate through a belt, one of them No. two gears meshes the internal transmission with another No. two gears during moving axis, synchronous drive No. two grinding rollers carry out the internal rotation during two No. two gear meshing transmissions, when starch piece falls through one-level grinding mechanism, enter into No. two feed inlets through the discharge plate and fall down, fall on No. two grinding rollers, make No. two grinding rollers carry out the secondary extrusion grinding to starch bits of broken glass, thereby make starch bits of broken glass ground into powdered, ground starch is because self weight freely falls down from No. two discharge gates.

As a preferred technical scheme of the invention, the conveying mechanism comprises a third rotating shaft, a conveying belt, sieve holes, baffles and a second belt, the third rotating shaft is symmetrically arranged between two vertical plates at the left and right ends close to the left and right ends through bearings, the two third rotating shafts are connected through the conveying belt in a conveying manner, the sieve holes are arranged on the upper end surface of the conveying belt and are distributed at equal intervals along the conveying belt, the baffles are arranged at the front end and the rear end of the conveying belt, the second rotating shaft at the left side is connected with the two third rotating shafts through the second belt in a driving manner, the second belt and the third rotating shafts are driven to rotate rightwards through the rotation of the second rotating shaft, ground starch falls onto the conveying belt when falling from a second discharge port, the conveying belt conveys the starch, the baffles prevent the starch from falling from the front side and the rear side when the conveying belt conveys the starch, the starch falls from the conveying, impurities in the starch remain on the conveyer belt and continue to be conveyed to the right end to be freely dropped.

As a preferred technical scheme of the invention, shaking rollers are symmetrically arranged between two vertical plates in a left-right mode through bearings, the two shaking rollers are positioned between two third rotating shafts, each shaking roller is provided with a plurality of semicircular protruding entities which are equidistantly arranged along the circumferential direction, chain wheels are fixedly sleeved on the two shaking rollers and one of the third rotating shafts close to the front end, the chain wheels are in transmission connection through chains, when the third rotating shafts rotate, the shaking rollers are synchronously driven to rotate through chain wheel and chain meshing transmission, and when the conveying belts convey starch, the shaking rollers shake the conveying belts, so that the conveying belts vibrate, starch on the conveying belts is quickly separated from impurities, and the working quality is improved.

As a preferred technical scheme of the invention, a first guide plate is arranged between two vertical plates, the first guide plate is installed in a downward inclined mode, a first material receiving box is arranged on the upper end face of a workbench and is positioned at the lower right side of the first guide plate, a first 21274is installed on the right end face of the first material receiving box, a shape pull handle is arranged on the right end face of the first material receiving box, impurities in starch fall on the first guide plate when falling from the right end of a conveyor belt, then the impurities slide into the first material receiving box from the first guide plate, the first material receiving box collects the impurities in the starch, and when the first material receiving box is filled with the impurities, the first material receiving box is pulled through the shape pull handle, so that the impurities in the first material receiving box can be conveniently treated.

As a preferable technical scheme, L-shaped plates are arranged on opposite surfaces of the two vertical plates, a second guide plate is arranged on the opposite surfaces of the vertical sections of the two L-shaped plates, the second guide plate is positioned between the two third rotating shafts and close to the upper side end and the lower side end of the conveyor belt, rotating holes corresponding to the two shaking rollers are formed in the upper end surface of the second guide plate, the two shaking rollers penetrate through the corresponding rotating holes, the front end and the rear end of the second guide plate are both inclined downwards, when starch falls from the conveyor belt through sieve holes, the starch falls onto the second guide plate, and then the starch slides from the second guide plate to the front side and the rear side.

As a preferred technical scheme of the invention, the upper end surface of the workbench is provided with a second material receiving box, the left end surface of the second material receiving box is provided with a second letter 21274, the second material receiving box is positioned below the conveyor belt, when starch slides down from the second guide plate to the front side and the rear side, the starch falls into the second material receiving box, the second material receiving box collects the starch, and when the second material receiving box is filled with the starch, the second material receiving box is pulled through the second letter 21274, so that the starch in the second material receiving box can be conveniently treated.

(II) advantageous effects

1. According to the organic starch production and processing system, the meshed first gears are adopted to drive the first grinding roller to rotate so as to grind and crush starch blocks, and then the meshed second gears drive the second grinding roller to rotate so as to grind and crush the crushed starch for the second time, so that the starch is crushed and ground into powder, the working efficiency is improved, and the manual labor force is reduced;

2. the conveyer belt make starch fall from the sieve mesh through the vibrations of trembling the roller when the conveying, impurity in the starch is stayed on the conveyer belt and falls when conveying to the right-hand member to make starch and impurity quick separation on the conveyer belt, improved work quality.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a front cross-sectional view of the present invention;

FIG. 4 is a top cross-sectional view of the present invention;

FIG. 5 is a left side elevation view of the present invention;

fig. 6 is a partial enlarged view of fig. 4 a according to the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways, which are defined and covered by the claims.

As shown in fig. 1 to 6, an organic starch production and processing system comprises a workbench 1, a primary grinding mechanism 2, a secondary grinding mechanism 3 and a conveying mechanism 4, wherein the primary grinding mechanism 2 is arranged above the workbench 1, the secondary grinding mechanism 3 is arranged below the primary grinding mechanism 2, and the conveying mechanism 4 is arranged below the secondary grinding mechanism 3.

The one-level grinding mechanism 2 comprises a vertical plate 20, a connecting rod 21, a grinding box 22, a feeding hole 23, a feeding plate 24, a discharging hole 25, a discharging plate 26, a rotating shaft 27, a grinding roller 28, a gear 29, a machine base 2a and a motor 2b, wherein the vertical plate 20 is symmetrically arranged in front and back of the upper end surface of the workbench 1, the connecting rod 21 is arranged on the opposite surfaces of the two vertical plates 20, the grinding box 22 is jointly arranged on the opposite surfaces of the two connecting rods 21, the left end and the right end of the grinding box 22 are circular arc-shaped cavity structures, the feeding hole 23 is arranged on the upper end surface of the grinding box 22, the feeding plate 24 with an outward opening is arranged on the feeding hole 23, the feeding plate 24 is rectangular, the discharging hole 25 is arranged on the lower end surface of the grinding box 22, and the discharging plate 26 with an inward opening is arranged on the discharging hole 25, the discharging plate 26 is rectangular, a first rotating shaft 27 is symmetrically arranged between the two vertical plates 20 in the left-right direction through a bearing, the two first rotating shafts 27 penetrate through the first grinding box 22, first grinding rollers 28 are fixedly sleeved on the two first rotating shafts 27, the two first grinding rollers 28 are arranged in the first grinding box 22, conical protruding entities are arranged on the two first grinding rollers 28 at equal intervals in the circumferential direction, first gears 29 are arranged on the two first rotating shafts 27, the two first gears 29 are in meshing transmission, a motor 2b is arranged on one vertical plate 20 through a machine base 2a, an output shaft of the motor 2b penetrates through the vertical plates 20 to be connected with one first rotating shaft 27, starch blocks are placed in the feeding plate 24 and fall onto the first grinding rollers 28 through the first feeding hole 23, the first rotating shaft 27 is driven to rotate through the motor 2b, and the first gear 29 is synchronously driven to rotate at the same time, gear 29 meshes the internal transmission with another gear 29 when rotating, and gear 29 meshes synchronous drive grinding roller 28 when internal transmission and carries out the internal rotation for grinding roller 28 extrudees the starch piece and grinds, thereby the starch piece is broken, and the starch piece that has been ground by grinding roller 28 extrusion drops through ejection of compact board 26 owing to self weight and a discharge gate 25.

The second-stage grinding mechanism 3 comprises a second connecting rod 30, a second grinding box 31, a second feeding hole 32, a second discharging hole 33, a second rotating shaft 34, a second grinding roller 35, a first belt 36 and a second gear 37, wherein the second connecting rod 30 is arranged on the opposite surfaces of the two vertical plates 20, the second grinding box 31 is jointly arranged on the opposite surfaces of the two second connecting rods 30, the left and right ends of the second grinding box 31 are arc-shaped cavity structures, the upper end surface of the second grinding box 31 is provided with the second feeding hole 32, the lower end surface of the second grinding box 31 is provided with the second discharging hole 33, the second rotating shaft 34 is symmetrically arranged between the two vertical plates 20 through a bearing in a left-right mode, the two second rotating shafts 34 penetrate through the second grinding box 31, the two second grinding rollers 35 are fixedly sleeved on the two second rotating shafts 34, and the two second grinding rollers 35 are arranged in the second grinding box 31, one of the first rotating shafts 27 is in transmission connection with one of the second rotating shafts 34 which correspond to the first rotating shaft up and down through a first belt 36, the two second rotating shafts 34 are fixedly sleeved with a second gear 37, the two second gears 37 are in meshing transmission, when the motor 2b drives the first rotating shaft 27 to rotate, one of the first rotating shafts 27 drives one of the second rotating shafts 34 to rotate with one of the second gears 37 through the first belt 36, one of the second gears 37 is in meshing inward transmission with the other second gear 37, when the two second gears 37 are in meshing transmission, the second grinding roller 35 is synchronously driven to rotate inwards, when starch blocks fall through the first-stage grinding mechanism 2 and enter the second feeding hole 32 through the discharging plate 26, the starch blocks fall onto the second grinding roller 35, so that the second grinding roller 35 performs secondary extrusion grinding on starch fragments, so that the starch is crushed and ground into powder, and the ground starch freely falls down from the second discharge port 33 due to the self weight.

The conveying mechanism 4 comprises a third rotating shaft 40, a conveying belt 41, sieve holes 42, baffle plates 43 and a second belt 44, the third rotating shaft 40 is symmetrically arranged between the two vertical plates 20 at the positions close to the left end and the right end in a bilateral mode and is installed through bearings, the two third rotating shafts 40 are connected through the conveying belt 41 in a conveying mode, the sieve holes 42 are formed in the upper end face of the conveying belt 41, the sieve holes 42 are distributed at equal intervals along the conveying belt 41, the baffle plates 43 are installed at the front end and the rear end of the conveying belt 41, the left second rotating shaft 34 is in transmission connection with the two third rotating shafts 40 through the second belt 44, the second belt 44 and the third rotating shaft 40 are driven to rotate rightwards through the rotation of the second rotating shaft 34, ground starch falls onto the conveying belt 41 when falling from the second discharge port 33, the conveying belt 41 conveys the starch, and the baffle plates 43, the starch falls from the conveyor belt 41 through the sieve holes 42 during the conveying of the conveyor belt 41, and impurities in the starch are left on the conveyor belt 41 and continue to be conveyed to the right end to be freely dropped.

Two vertical board 20 between bilateral symmetry install through the bearing and shake roller 201, two shake roller 201 and be located between two No. three axis of rotation 40, two shake roller 201 and one of them No. three axis of rotation 40 go up and all be equipped with sprocket 202 near the equal fixed cover of front end, connect through chain 203 transmission between the sprocket 202, it shakes roller 201 to rotate through sprocket 202 chain 203 meshing transmission synchronization drive when No. three axis of rotation 40 rotates, it shakes roller 201 to convey the area 41 to tremble to shake in conveyer belt 41 when conveyer belt 41 conveys starch, make conveyer belt 41 shake, thereby make starch and impurity quickly separating on the conveyer belt 41, and the work quality is improved.

A guide plate 204 is installed between two vertical plates 20, the guide plate 204 is installed in a downward inclined mode, a material receiving box 205 is arranged on the upper end face of the workbench 1, the material receiving box 205 is located on the right lower portion of the guide plate 204, a v-shaped 21274is installed on the right end face of the material receiving box 205, a shape pull handle 206 falls on the guide plate 204 when impurities in starch fall from the right end of the conveyor belt 41, then the impurities fall into the material receiving box 205 from the guide plate 204, the impurities in the starch are collected by the material receiving box 205, and when the material receiving box 205 is filled with the impurities, the shape pull handle 206 pulls the material receiving box 205 to facilitate treatment of the impurities in the material receiving box 205.

Two the opposite face of vertical board 20 all install L shaped plate 207, two vertical section opposite faces of L shaped plate 207 install No. two deflector plates 208 jointly, No. two deflector plates 208 are located between two No. three axis of rotation 40 and are close to conveyer belt 41's upside end and lower side, No. two deflector plates 208 up end seted up with two shake corresponding rotation hole 209 of roller 201, two shake roller 201 and run through corresponding rotation hole 209 that wears, No. two equal downward sloping in both ends around deflector plate 208, when starch passes through sieve mesh 42 and falls down from conveyer belt 41, fall on No. two deflector plates 208, then starch is followed No. two deflector plates 208 and is gone up to both sides landing around to.

1 up end be provided with No. two and connect workbin 10, No. two connect workbin 10 left end face and install No. two \ 21274, the shape is drawn 11, No. two connect workbin 10 and is located the below of conveyer belt 41, when starch from No. two deflector 208 to the front and back both sides landing, fall into No. two and connect workbin 10, No. two connect workbin 10 and collect starch, when starch fill No. two connect workbin 10, through drawing No. two \ 21274, the shape is drawn 11 and is drawn No. two and connect workbin 10, be convenient for handle the starch in No. two connect workbin 10.

When the starch grinding machine works specifically, starch blocks are placed in the feeding plate 24 and fall onto the first grinding roller 28 through the first feeding hole 23, the motor 2b rotates to drive one of the first rotating shafts 27 to rotate and simultaneously synchronously drive the first gear 29 to rotate, the first gear 29 rotates to be meshed with the other first gear 29 for inward transmission, the first grinding roller 28 is synchronously driven to rotate inward when the first gear 29 is meshed for inward transmission, so that the first grinding roller 28 extrudes and grinds the starch blocks, the starch blocks are crushed, the starch blocks extruded and ground by the first grinding roller 28 fall through the discharging plate 26 due to the self weight of the starch blocks, one of the first rotating shafts 27 drives one of the second rotating shafts 34 to rotate with one of the second gears 37 through the first belt 36, one of the second gears 37 moves inwards through meshing with the other second gear 37, the two second gears 37 synchronously drive the second grinding roller 35 to rotate inwards during meshing transmission, when starch blocks fall through the first-stage grinding mechanism 2 and enter the second feeding hole 32 through the discharging plate 26 to fall onto the second grinding roller 35, the second grinding roller 35 carries out secondary extrusion grinding on starch fragments, so that the starch fragments are ground into powder, the ground starch freely falls from the second discharging hole 33 due to the self weight, the second rotating shaft 34 rotates to drive the second belt 44 and the third rotating shaft 40 to rotate rightwards at the moment, when the ground starch falls from the second discharging hole 33, the ground starch falls onto the conveyor belt 41, the conveyor belt 41 conveys the starch, the baffle plate 43 prevents the conveyor belt 41 from falling from the front side and the rear side when conveying the starch, and meanwhile, the third rotating shaft 40 rotates to synchronously drive the shaking roller 201 to rotate through the chain wheel 202 and the chain 203 meshing transmission, the conveying belt 41 is shaken by the shaking roller 201 while the conveying belt 41 conveys the starch, so that the conveying belt 41 is shaken, the starch on the conveying belt 41 is quickly separated from impurities, the working quality is improved, the starch falls from the conveying belt 41 through the sieve holes 42 and falls onto the second guide plate 208, then the starch slides from the second guide plate 208 to the front side and the rear side and falls into the second receiving box 10, the second receiving box 10 collects the starch, when the starch is filled in the second receiving box 10, the second receiving box 10 is pulled by the shape pull handle 11 to facilitate the treatment of the starch in the second receiving box 10, the impurities in the starch are remained on the conveying belt 41 and continuously conveyed to the right end to freely fall off and fall onto the first guide plate 204, then the impurities fall into the first receiving box 205 from the first guide plate 204, and the impurities in the starch are collected by the first receiving box 205, when the first material receiving box 205 is filled with impurities, the first material receiving box 205 is pulled by the first lifting handle 206, so that the impurities in the first material receiving box 205 are conveniently treated.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. The utility model provides an organic starch production system of processing, includes workstation (1), one-level grinding mechanism (2), second grade grinding mechanism (3) and transport mechanism (4), its characterized in that: a primary grinding mechanism (2) is arranged above the workbench (1), a secondary grinding mechanism (3) is arranged below the primary grinding mechanism (2), and a conveying mechanism (4) is arranged below the secondary grinding mechanism (3);

the primary grinding mechanism (2) comprises vertical plates (20), a first connecting rod (21), a first grinding box (22), a first feeding hole (23), a feeding plate (24), a first discharging hole (25), a discharging plate (26), a first rotating shaft (27), a first grinding roller (28), a first gear (29), a machine base (2a) and a motor (2b), wherein the vertical plates (20) are symmetrically arranged in front and back of the upper end face of the workbench (1), the first connecting rod (21) is respectively arranged on the opposite faces of the two vertical plates (20), the first grinding box (22) is jointly arranged on the opposite faces of the two first connecting rods (21), the left end and the right end of the first grinding box (22) are arc-shaped cavity structures, the first feeding hole (23) is arranged on the upper end face of the first grinding box (22), and the feeding plate (24) with an outward opening is arranged on the first feeding hole (23), the feeding plate (24) is rectangular, a first discharging hole (25) is formed in the lower end face of a first grinding box (22), a discharging plate (26) with an inward opening is installed on the first discharging hole (25), the discharging plate (26) is rectangular, a first rotating shaft (27) is installed between two vertical plates (20) in bilateral symmetry through a bearing, the two first rotating shafts (27) penetrate through the first grinding box (22), first grinding rollers (28) are fixedly sleeved on the two first rotating shafts (27), the two first grinding rollers (28) are arranged in the first grinding box (22), conical protruding entities are arranged on the two first grinding rollers (28) at equal intervals in the circumferential direction, first gears (29) are installed on the two first rotating shafts (27), the two first gears (29) are in meshing transmission, a motor (2b) is installed on one vertical plate (20) through a machine base (2a), an output shaft of the motor (2b) penetrates through the vertical plate (20) and is connected with one first rotating shaft (27);

the secondary grinding mechanism (3) comprises a second connecting rod (30), a second grinding box (31), a second feeding hole (32), a second discharging hole (33), a second rotating shaft (34), a second grinding roller (35), a first belt (36) and a second gear (37), wherein the second connecting rod (30) is arranged on the opposite surface of each of the two vertical plates (20), the second grinding box (31) is jointly arranged on the opposite surface of each of the two second connecting rods (30), the left end and the right end of each of the two grinding boxes (31) are arc-shaped cavity structures, the second feeding hole (32) is formed in the upper end surface of each of the two grinding boxes (31), the second discharging hole (33) is formed in the lower end surface of each of the two grinding boxes (31), the two rotating shafts (34) are symmetrically arranged between the two vertical plates (20) through bearings, and both the two second rotating shafts (34) penetrate through the two grinding, all fixed the cover be equipped with No. two grinding roller (35) on No. two axis of rotation (34), two No. two grinding roller (35) are in No. two grinding case (31), and one of them axis of rotation (27) is connected through a belt (36) transmission with one of them No. two axis of rotation (34) that correspond from top to bottom, and all fixed the cover be equipped with No. two gear (37) on two No. two axis of rotation (34), and two No. two gear (37) are the meshing transmission.

2. The system for producing and processing organic starch according to claim 1, wherein: transport mechanism (4) including No. three axis of rotation (40), conveyer belt (41), sieve mesh (42), baffle (43) and No. two belt (44), two vertical board (20) between bilateral symmetry be close to about both ends department and install No. three axis of rotation (40) through bearing, connect through conveyer belt (41) conveying between two No. three axis of rotation (40), sieve mesh (42) have been seted up to conveyer belt (41) up end, sieve mesh (42) are arranged along conveyer belt (41) equidistance, baffle (43) are all installed at both ends around conveyer belt (41), No. two axis of rotation (34) in left side and two No. three axis of rotation (40) are connected through No. two belt (44) transmissions.

3. The system for producing and processing organic starch according to claim 2, wherein: two vertical board (20) between bilateral symmetry install through the bearing and shake roller (201), two shake roller (201) and be located between two No. three axis of rotation (40), two shake roller (201) and all have a plurality of protruding entities of arranging semicircle form along circumference equidistance, two shake roller (201) and one of them No. three axis of rotation (40) go up and be close to the equal fixed cover of front end and be equipped with sprocket (202), connect through chain (203) transmission between sprocket (202).

4. The system for producing and processing organic starch according to claim 1, wherein: two vertical board (20) between install deflector (204), deflector (204) downward sloping installation, workstation (1) up end is provided with a material receiving box (205), and a material receiving box (205) is located the right below of deflector (204), and a material receiving box (205) right-hand member face installs one number, (21274) shape is drawn handle (206).

5. The system for producing and processing organic starch according to claim 3, wherein: two the opposite face of vertical board (20) all install L shaped plate (207), two vertical section opposite faces of L shaped plate (207) install No. two deflector (208) jointly, No. two deflector (208) are located between two No. three axis of rotation (40) and are close to the last side and the lower side of conveyer belt (41), No. two deflector (208) up end seted up with two corresponding rotation hole (209) of shaking roller (201), two shake roller (201) and run through corresponding wear rotation hole (209), the equal downward sloping in both ends around No. two deflector (208).

6. The system for producing and processing organic starch according to claim 2, wherein: the upper end surface of the workbench (1) is provided with a second material receiving box (10), the left end surface of the second material receiving box (10) is provided with a second 21274, the shape pull handle (11), and the second material receiving box (10) is positioned below the conveyor belt (41).

Images